This changes a bunch of places which use getAs<TagType>, including
derived types, just to obtain the tag definition.

This is preparation for #155028, offloading all the changes that PR used
to introduce which don't depend on any new helpers.

Fixes #149866

---------

Co-authored-by: Aaron Ballman <aaron@aaronballman.com>

The 'cfi_salt' attribute specifies a string literal that is used as a
"salt" for Control-Flow Integrity (CFI) checks to distinguish between
functions with the same type signature. This attribute can be applied
to function declarations, function definitions, and function pointer
typedefs.

This attribute prevents function pointers from being replaced with
pointers to functions that have a compatible type, which can be a CFI
bypass vector.

The attribute affects type compatibility during compilation and CFI
hash generation during code generation.

  Attribute syntax: [[clang::cfi_salt("<salt_string>")]]
  GNU-style syntax: __attribute__((cfi_salt("<salt_string>")))

- The attribute takes a single string of non-NULL ASCII characters.
- It only applies to function types; using it on a non-function type
  will generate an error.
- All function declarations and the function definition must include
  the attribute and use identical salt values.

Example usage:

  // Header file:
  #define __cfi_salt(S) __attribute__((cfi_salt(S)))

  // Convenient typedefs to avoid nested declarator syntax.
  typedef int (*fp_unsalted_t)(void);
  typedef int (*fp_salted_t)(void) __cfi_salt("pepper");

  struct widget_ops {
    fp_unsalted_t init;     // Regular CFI.
    fp_salted_t exec;       // Salted CFI.
    fp_unsalted_t teardown; // Regular CFI.
  };

  // bar.c file:
  static int bar_init(void) { ... }
  static int bar_salted_exec(void) __cfi_salt("pepper") { ... }
  static int bar_teardown(void) { ... }

  static struct widget_generator _generator = {
    .init = bar_init,
    .exec = bar_salted_exec,
    .teardown = bar_teardown,
  };

  struct widget_generator *widget_gen = _generator;

  // 2nd .c file:
  int generate_a_widget(void) {
    int ret;

    // Called with non-salted CFI.
    ret = widget_gen.init();
    if (ret)
      return ret;

    // Called with salted CFI.
    ret = widget_gen.exec();
    if (ret)
      return ret;

    // Called with non-salted CFI.
    return widget_gen.teardown();
  }

Link: https://github.com/ClangBuiltLinux/linux/issues/1736
Link: https://github.com/KSPP/linux/issues/365

---------

Signed-off-by: Bill Wendling <morbo@google.com>
Co-authored-by: Aaron Ballman <aaron@aaronballman.com>

This is a major change on how we represent nested name qualifications in
the AST.

* The nested name specifier itself and how it's stored is changed. The
prefixes for types are handled within the type hierarchy, which makes
canonicalization for them super cheap, no memory allocation required.
Also translating a type into nested name specifier form becomes a no-op.
An identifier is stored as a DependentNameType. The nested name
specifier gains a lightweight handle class, to be used instead of
passing around pointers, which is similar to what is implemented for
TemplateName. There is still one free bit available, and this handle can
be used within a PointerUnion and PointerIntPair, which should keep
bit-packing aficionados happy.
* The ElaboratedType node is removed, all type nodes in which it could
previously apply to can now store the elaborated keyword and name
qualifier, tail allocating when present.
* TagTypes can now point to the exact declaration found when producing
these, as opposed to the previous situation of there only existing one
TagType per entity. This increases the amount of type sugar retained,
and can have several applications, for example in tracking module
ownership, and other tools which care about source file origins, such as
IWYU. These TagTypes are lazily allocated, in order to limit the
increase in AST size.

This patch offers a great performance benefit.

It greatly improves compilation time for
[stdexec](https://github.com/NVIDIA/stdexec). For one datapoint, for
`test_on2.cpp` in that project, which is the slowest compiling test,
this patch improves `-c` compilation time by about 7.2%, with the
`-fsyntax-only` improvement being at ~12%.

This has great results on compile-time-tracker as well:

![image](https://github.com/user-attachments/assets/700dce98-2cab-4aa8-97d1-b038c0bee831)

This patch also further enables other optimziations in the future, and
will reduce the performance impact of template specialization resugaring
when that lands.

It has some other miscelaneous drive-by fixes.

About the review: Yes the patch is huge, sorry about that. Part of the
reason is that I started by the nested name specifier part, before the
ElaboratedType part, but that had a huge performance downside, as
ElaboratedType is a big performance hog. I didn't have the steam to go
back and change the patch after the fact.

There is also a lot of internal API changes, and it made sense to remove
ElaboratedType in one go, versus removing it from one type at a time, as
that would present much more churn to the users. Also, the nested name
specifier having a different API avoids missing changes related to how
prefixes work now, which could make existing code compile but not work.

How to review: The important changes are all in
`clang/include/clang/AST` and `clang/lib/AST`, with also important
changes in `clang/lib/Sema/TreeTransform.h`.

The rest and bulk of the changes are mostly consequences of the changes
in API.

PS: TagType::getDecl is renamed to `getOriginalDecl` in this patch, just
for easier to rebasing. I plan to rename it back after this lands.

Fixes #136624
Fixes https://github.com/llvm/llvm-project/issues/43179
Fixes https://github.com/llvm/llvm-project/issues/68670
Fixes https://github.com/llvm/llvm-project/issues/92757

The checks for the 'z' and 't' format specifiers added in the original
PR #143653 had some issues and were overly strict, causing some build
failures and were consequently reverted at
https://github.com/llvm/llvm-project/commit/4c85bf2fe8042c855c9dd5be4b02191e9d071ffd.

In the latest commit
https://github.com/llvm/llvm-project/pull/149613/commits/27c58629ec76a703fde9c0b99b170573170b4a7a,
I relaxed the checks for the 'z' and 't' format specifiers, so warnings
are now only issued when they are used with mismatched types.

The original intent of these checks was to diagnose code that assumes
the underlying type of `size_t` is `unsigned` or `unsigned long`, for
example:

```c
printf("%zu", 1ul); // Not portable, but not an error when size_t is unsigned long
```  

However, it produced a significant number of false positives. This was
partly because Clang does not treat the `typedef` `size_t` and
`__size_t` as having a common "sugar" type, and partly because a large
amount of existing code either assumes `unsigned` (or `unsigned long`)
is `size_t`, or they define the equivalent of size_t in their own way
(such as
sanitizer_internal_defs.h).https://github.com/llvm/llvm-project/blob/2e67dcfdcd023df2f06e0823eeea23990ce41534/compiler-rt/lib/sanitizer_common/sanitizer_internal_defs.h#L203

This reverts commit c27e283cfbca2bd22f34592430e98ee76ed60ad8.

A builbot failure has been reported:
https://lab.llvm.org/buildbot/#/builders/186/builds/10819/steps/10/logs/stdio

I'm also getting a large number of warnings related to %zu and %zx.

Including the results of `sizeof`, `sizeof...`, `__datasizeof`,
`__alignof`, `_Alignof`, `alignof`, `_Countof`, `size_t` literals, and
signed `size_t` literals, the results of pointer-pointer subtraction and
checks for standard library functions (and their calls).

The goal is to enable clang and downstream tools such as clangd and
clang-tidy to provide more portable hints and diagnostics.

The previous discussion can be found at #136542.

This PR implements this feature by introducing a new subtype of `Type`
called `PredefinedSugarType`, which was considered appropriate in
discussions. I tried to keep `PredefinedSugarType` simple enough yet not
limited to `size_t` and `ptrdiff_t` so that it can be used for other
purposes. `PredefinedSugarType` wraps a canonical `Type` and provides a
name, conceptually similar to a compiler internal `TypedefType` but
without depending on a `TypedefDecl` or a source file.

Additionally, checks for the `z` and `t` format specifiers in format
strings for `scanf` and `printf` were added. It will precisely match
expressions using `typedef`s or built-in expressions.

The affected tests indicates that it works very well.

Several code require that `SizeType` is canonical, so I kept `SizeType`
to its canonical form.

The failed tests in CI are allowed to fail. See the
[comment](https://github.com/llvm/llvm-project/pull/135386#issuecomment-3049426611)
in another PR #135386.

getExceptionMode() already returns LangOptions::FPExceptionModeKind.

This is similar to -msve-vector-bits, but for streaming mode: it
constrains the legal values of "vscale", allowing optimizations based on
that constraint.

This also fixes conversions between SVE vectors and fixed-width vectors
in streaming functions with -msve-vector-bits and
-msve-streaming-vector-bits.

This rejects any use of arm_sve_vector_bits types in streaming
functions; if it becomes relevant, we could add
arm_sve_streaming_vector_bits types in the future.

This doesn't touch the __ARM_FEATURE_SVE_BITS define.